Apparatus and method for continuous filtering



W. S. EAKINS Aug. 12, 1969 APPARATUS AND METHOD FOR CONTINUOUS FILTERING Filed De e. 21, 1966 15 Sheets-Sheet 1 INVEN'IOR. Mum v 6. [Jaw/ms Aug. 12, 1969 w. s. EAKINS 3,460,674

APPARATUS AND METHOD FOR CONTINUOUS FILTERING Filed Dec. 21, 1966 15 Sheets-Sheet 2 a- 2 96 w. s. EAKINQ' 3,460,674

APPARATUS AND METHOD FOR CONTINUOUS FILTERING Filed Dec. 21, 1966 15 Sheets-Sheet 5 W. S. EAKINS Aug. 12, 196 9 APPARATUS AND METHOD FOR CONTINUOUS FILTERING Filed Dec. 21, 1966 15 Sheets-Sheet 4 INVEN'I'OR. Mac/47 6'. 54mm Aug. 2, 1969 w. 5. Wm 3,460,674

APPARATUS AND METHOD FOR CONTINUOUS FILTERING Filed Dec. 21, 1966 15 Sheets-Sheet 5 F INVENTOR. MLu /w a [a K/NS W ZWOQNGYS W. S. EAKINS Aug. 12, 1969 APPARATUS AND METHOD FOR CONTINUOUS FILTERING Filed Deb. 21, 1966 15 Sheets-Sheet 6 INVENTOR. Mac/4M 6. 591W BY 5 Arm/v06 s- 2, 1969 w. s. EAKINS 3,460,674

APPARATUS AND METHOD FOR CONTINUOUS FILTERING Filed D90. 21, 1965 15 Sheets-Sheet 7 Z7 INVENTUR.

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I APPARATUS AND METHOD FOR CONTINUOUS FILTERING Filed Dec. 21. 1966 15 Sheets-Sheet 9 INVENTOR.

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APPARATUS AND METHOD FOR CONTINUOUS FILTERING Filed Dec. 21. 1966 15 Sheets-Sheet 1O Aug. 2, 1969 w. s. EAKINS 3,460,674

APPARATUS AND METHOD FOR CONTINUOUS FILTERING Filed Dec. 21, 1966 15 Sheets-Sheet 11 l Mum '7 5 Orv vs 2, 1969 w. s. EAKINS 3,460,674

APPARATUS AND METHOD FOR CONTINUOUS FILTERING Filed Dec. 21, 1966 15 Sheds-Sheet 1s ZiA-FYJ Aug 12, 1969 w. s. EAKINS 3,460,674

' APPARATUS AND METHOD FOR CONTINUOUS FILTERING Filed Dec. 21, 1966 15 Sheets-Sheet 1 Tic fi 7.

W. S. EAKINS Aug. 12, 1969 APPARATUS AND METHOD FOR CONTINUOUS FILTERING Filed D60. 21, 1966 15 Sheets-Sheet 15 7 \w mN Lu N V ww JNVEN'TOR. 0/440? 6? EEK/N6 BY a z i 14'7" TOR/V5 45 I. II I. O O O O O O I I 0 u v 7 L7 an. L 1. l a an an an. 0 n. .u a v nyml nm United States Patent 3,460,674 APPARATUS AND METHOD FOR CONTINUOUS FILTERING William S. Eakins, St. Andrews Lane, Glen Cove, NY. 11542 Contmuation-in-part of application Ser. No. 578,361, Sept. 9, 1966. This application Dec. 21, 1966, Ser. No. 613,691

Int. Cl. B01d 33/02, 33/00 US. Cl. 21077 33 Claims ABSTRACT OF THE DISCLOSURE This is a continuation in part of applicants copending application Ser. No. 578,361, filed Sept. 9, 1966, now abandoned.

This invention relates to continuous filtering and more in particular to a traveling filter in which vacuum is applied to the filter medium as it is conveyed.

In prior art continuous or traveling filters several dif ferent difiiculties have commonly been encountered. One difiiculty is that of aplying a flow of fluid, whether it be induced by a pressure or a vacuum source, to the traveling filter in order to treat the filter cake being accumulated upon the filter medium. During and after the delivery of the material to be filtered to the filter medium which can be mounted upon a filter tray, it is generally necessary to apply a vacuum condition in order to draw the liquid portion of the material through the filter medium and thereby separate and build up a filter cake upon the medium. Since filtering apparatus commonly employs an endless belt of appreciable length of a plurality of traveling filter trays and since it is usually necessary to apply a vacuum or pressure condition to the belt or trays over an extensive period of travel, it becomes difiicult to provide the necessary equipment for subjecting the belt or each of the filter trays at least through part of their travel throughout the apparatus to a vacuum or pressure condition without involving undue complexity or shortened life for the equipment.

In the prior art, vacuum has been applied to an endless belt or to the separate trays of a traveling filter by providing an elongated suction box over which the belt or trays are advanced. Since it is necessary to form a seal between the bottom portion of the belt or the trays and the suction box, the resulting arrangement is generally subject to excessive leakage and a comparatively high rate of wear between the fixed and stationary portions of the seal.

Another ditficulty encountered with traveling filters has been that of obtaining an eflicient, reliable and durable arrangement for removing the filter cake after its formation upon the filter medium. Wherever a plurality of continuously moving trays each having a filter medium are employed, difiiculty is experienced in removing the filter cake from the tray since the cake tends to cling firmly to the tray and to the filter medium even though the tray is inverted after the formation of the filter cake. Where each tray is provided with side walls of sufiicient height to receive and confine a substantial quantity of material to be filtered, the side walls of the tray present a greater area to which the filter cake can cling and adhere during 3,460,674 Patented Aug. 12, 1969 attempts to remove the cake from the tray. Attempts to insure removal of the cake from the tray by the application of reverse blasts or jets of pressure fluid to the filter cake have also resulted in complicated designs which still fail to provide for the simple and reliable removal of the filter cake from the filter medium within the tray.

It Is therefore one of the objects of the invention to provide a traveling filter to which a flow of pressured or vacuum fluid can be applied without the need of continuously sliding seals or the like between the filter trays and the source of the flow of pressured or vacuum fluid.

It is another object of the invention to provide a traveling filter in which the duration of the applying of pressure or vacuum to the filter trays can be accurately controlled.

It is still another object of the invention to provide a traveling filter in which pressure or vacuum can be applied in a controlled manner with respect to each of the filter trays independently of one another.

It is an additional object of the invention to provide a traveling filter in which fluid can be applied with respect to each tray individually even though the filter travels over an appreciable distance.

It is a further object of the invention to provide a traveling filter in which the construction of the trays is conditioned to facilitate the release and the removal of the filter cake.

It is still a further object of the invention to provide a traveling filter in which the material to be filtered and the resulting filter cake is confined to the filter medium only during a portion of the travel of the tray.

It is another object of the invention to remove filter cakes from a traveling filter in a clean etficient manner.

It is another object of the invention to intermittently feed the trays of a traveling filter in sequential manner.

It is also an object of the invention to provide a traveling filter in which the filter medium of each of the trays can be operated to facilitate the removal of the filter cake therefrom.

In one of the embodiments of the invention the traveling filter includes a plurality of tray members each having a filter medium which is adapted to receive material to be filtered. Each of the plurality of tray member has a passage for passing a flow of fluid with respect to the tray member. Means are provided for conveying the plurality of tray members along a predetermined path. At least one conduit adapted to be connected to a device for producing a flow of fiuid is provided. In addition, means are provided for driving the conduit along an additional path adjacent to at least a portion of the predetermined path of the tray members. Means are also provided for successively advancing and retracting the conduit with respect to its additional path as the conduit is driven in order successively to engage and disengage the conduit with respect to the passage of the tray member as the tray member is conveyed.

An advantage of this arrangement is that the operation of the conduit can be conveniently established at various locations along the predetermined path of the tray members since the conduit is driven adjacent to the path of the tray members and since the conduit is advanced and retracted with respect to its own path. An additional advantage is that it enables a flow of fluid to be controlled with respect to each individual tray member independently of the remaining tray members. Another advantage is that the advancing and retracting of the conduit enables the passage of the tray member to be engaged and disengaged at various locations along its predetermined path of travel without interfering with the conveying of the tray member.

In another embodiment of the invention the tray mem- 3 bers are provided with a cavity with which the passage is in communication and over which the filter medium is disposed. This construction enables the conduit to establish a flow of fluid with respect to the filter medium by way of the cavity.

In still another embodiment of the invention the filter medium of each of the plurality of tray members extends in a substantially horizontal plane throughout at least a portion of the predetermined path of the tray members in order to assist the accumulation of a filter cake upon the filter medium.

In addition embodiment of the invention the conduit comprises a tubular member which is adapted to successively engage and disengage the passage of the tray member in order to establish a flow of fluid with respect to the tray member.

In a further embodiment of the invention the traveling filter comprises a plurality of tray members each having a filter medium and means for conveying the tray members along a predetermined path. The filter further includes a plurality of frame members each having an opening adapted to mate in a facing relationship with the surface area of the filter medium. Means are provided for moving the plurality of frame members along another path extending at least in part adjacent to the predetermined path of the tray members in order successively to place and remove the opening of each of a portion of the plurality of frame members with respect to a condition of registry and substantial engagement with a different one of the tray members of a corresponding portion of the plurality of tray members.

An advantage of this arrangement is that the frame members are adapted to confine the material to be filtered upon the filter medium adjacent thereto. Subsequently, upon removal of the frame members from in registry and substantial engagement with the tray members, the removal of the filter cakes from the filter mediums is facilitated and made more positive.

In still a further embodiment of the invention the conveying means for the plurality of tray members and the plurality of frame members each have upper and lower reaches with at least a portion of the lower reach of the frame members overlying and sutficiently adjacent to the upper reach of the tray members in order to enable the frame members to be placed in registry and substantial engagement with the tray members.

In another embodiment of the invention the traveling filter includes means for delivering the material to be filtered through the openings of the frame members as the frame members are moved along the lower reach of their conveying means.

In another embodiment, a hopper is positioned within the reach of the conveying means to be filled with feed material and intermittently pivoted in response to the presence of a tray underneath to dump its contents into successive trays.

In a still further embodiment of the invention, the traveling filter has a take-up roller mounted adjacent a conveying means and a pair of scraper blades. The takeup roller is provided with ports in the surface which communicate with a vacuum source to hold the cake material and the blades are arranged so that one scrapes a filter cake onto the roller and the other scrapes an upper layer of cake material from the roller at an advanced position.

Various other objects and advantages of the present invention will be readily apparent from the following detailed description when considered in connection with the accompanying drawings in which:

FIG. 1 is an elevational view of the traveling filter of the invention showing the lower reach of the conveyor of the frame members overlying and in substantial engagement with the upper reach of the conveyor of the tray members with means for successivel advancing and retracting the conduits disposed adjacent to the upper reach of the conveyor for the tray members;

FIG. 2 is a fragmentary elevational view of the traveling filter showing the means for driving the conduits along an additional path adjacent to a portion of the predetermined path of the tray members;

FIG. 3 is a fragmentary plan view of the conveyor for the tray members showing the conduits and the means for driving the conduits along an additional path adjacent to a portion of the predetermined path of the conveyor of the tray members;

FIG. 4 is a plan view of a single one of the assemblies of conduits with the means for successively advancing and retracting the conduits as they are driven with respect to the conveyor for the tray members;

FIG. 5 is a vertical section view taken along the line 5-5 in FIG. 4 and showing the control valve arrangement for the flow of fluid through the conduits;

FIG. 6 is a vertical section view taken along the line 6-6 of FIG. 5 and showing the means for driving the conduits along an additional path adjacent to the predetermined path of the tray members;

FIG. 7 is a perspective view of one of the plurality of tray members and one of the plurality of frame members in registry and substantially engaged with the tray member;

FIG. 8 is a vertical section view taken along a plane extending parallel to the line of travel of the tray member and showing the cavity, the filter medium and the passage of the tray member;

FIG. 9 is a plan view of one of the tray members showing the filter medium overlying the plate of the tray member;

FIG. 10 is an elevational view of the end portion of a passage connected to a tray member showing the alternate titled portions which the passage can assume with respect to its support;

FIG. 11 is a vertical section view taken along the line 111 in FIG. 8 and showing the passage and the valve connected thereto for a tray member in alignment with the conduit;

. FIG. 12 is a fragmentary vertical section view showing the opening of a conduit advancing into engagement with the valve of the passage leading to the tray member;

FIG. 13 is a fragmentary vertical section view showing the opening of the conduit fully engaged with the open valve of the passage leading to the tray member;

FIG. 14 is a fragmentary vertical section view of the conveyors for the frame members and the tray members and showing the filter cake being released from the tray member after removal of the frame member;

FIG. 15 is a fragmentary vertical section view showing a detachable filter medium for facilitating the removal of the filter cake;

FIG. 16 is a fragmentary vertical section view showing means for assisting in the removal of the filter cake from the detachable filter medium;

FIG. 17 is a fragmentary vertical section view showing a roller and a scraper blade for removing the filter cake from the filter medium.

FIG. 18 is an elevational view showing an arrangement for camming the tops into engagement with the trays as the tops and trays advance.

FIG. 19 is a fragmentary vertical section view taken along the line 1919 in FIG. 18 and showing the suspension of the top with respect to the chains and the means for camming the top into engagement with the tray.

FIG. 20 is a fragmentary vertical section view showing a top disposed upon the tray with the filter cake extending into contact with the top;

FIG. 21 is a fragmentary vertical section view showing the top disposed upon the tray with the filter cake offset from the top;

FIG. 22 is a cross section view of a modified structure for removing the filter cake from the filter medium;

FIG. 23 is a side view of the modified structure of FIG. 22;

FIG. 24 is a view of the drive for the modified structure of FIG. 22;

FIG. 25 is a view of the modified structure for removing the filter cake from a filter apparatus of different Construction;

FIG. 26 is a fragmentary vertical section view of an intermittent delivery means for the trays;

FIG. 27 is a perspective view of a modified intermittent delivery means;

FIG. 28 is a modified assembly of conduits; and

FIG. 29 is a vertical section view of a modified tray for use with the conduits of FIG. 28.

The traveling filter of the invention includes a plurality of tray members or trays connected to and driven by conveying means or endless conveymg chains 21 along the predetermined path which includes upperreach 21a and lower reach 21b (FIGS. 1 and 2). Chams 21 are driven in the direction shown by the arrows in FIGS. 1 and 2 by at least one of sprockets 22. The upper and lower reaches of chains 21 extend in a substantially horizontal direction.

Trays 20 include side walls 23 and bottom walls 24 which form cavity 25 (FIGS. 7, 8 and 9). The trays are supported with respect to chain 21 by means of legs 26 attached to side walls 23. One pair of legs 26 are provlded with openings 26a through which bolts 27 extend. Bolts 27 Which are mounted in brackets 28 and engage wheels 29 serve as axles for supporting legs 26 with respect to the wheels and thereby with respect to rails 30. The attachment of brackets 28 to chains 21 enables the chains to drive or convey the trays. The remaining pair of legs 26 are similarly mounted with the exception that bolt 27 passes through slot 26b which extends in a horizontal direction. The clearance of bolt 27 in slot 26b prevents legs 26 from attempting to restrain the chains whenever the trays are carried by the chains along a circular path extending from one reach to the other of the conveyor.

Cavity 25 of tray 20 is covered by plate 31 containing a plurality of openings 31a which extend from serrations or grooves 31b arranged in a grid-like pattern across the plate. Filter medium 32 overlies plate 31 and is supported by the plate with respect to cavity 25. The filter medium which can comprise cloth, wire cloth, porous materials, etc. is stretched in a taut manner across plate 31 by means of rods 33 mounted upon side walls 23.

Along upper reach 21a wheels 29 support the weight of the tray upon rails 30. In the inverted position of tray 20 as it travels along lower reach 21b of the conveyor, the tray hangs by means of legs 26 and brackets 28 from chains 21. Along the upper reach, filter medium 32 extends in a substantially horizontal plane in order that it may receive a substantially uniform layer of material to be filtered.

Frame members or tops 34 are supported by legs 35 attached to side walls 36 (FIGS. 1, 2 and 7). The support of legs 35 and their engagement with the moving means or conveyor chains 37 can be similar to that of legs 26 of the trays with respect to chains 21. End walls 38 of tops 34 form an opening which is adapted to mate in a facing relationship with the surface area of filter medium 32.

Chains 37 include upper reaches 37a and lower reaches 37b which extend about sprockets 39 and are driven by at least one of them. The assembly of conveyor chains 37 with tops 34 is positioned so that edges 36a and 38a of the walls of the top can be placed in substantial engagement with filter medium 32 along the lower reach of the conveyor for the tops and the upper reach of the conveyor for the trays. With this arrangement, the tops can confine the material to be filtered which i directed into the tops by delivering means such as pipe 40 (FIGS. 1 and 2). As shown in FIG. 7 edges 36a of the side walls can bear directly upon plate 31 while edges 38a of the end walls bear upon filter medium 32. The engagement between the tops and the trays is adjusted to prevent leakage between the tops and the trays as they travel mated together. Edges 36a and 38a can be covered with suitable resilient material such as elastomeric material in order to form a seal between the tops and the trays.

Each of the plurality of trays is provided with structure forming a passage for passing a flow of fluid with respect to the tray. The passage includes pipe 41 connected by hose 42 to fitting 43 mounted in opening 44 of side walls 23 (FIGS. 8 and 11). Pipe 41 is secured to arms 45 which are in turn attached to pin 46. Pin 46 is pivotally mounted in support 47 and the engagement of pin 46 with support 47 i conditioned to permit arms 45 to swing toward each side of the vertical extending from pin 46. For example, the pins can be conditioned to limit the swing of the arms to each side of the vertical to an are approximately in the range of about 45 to 9Q (FIG. 10). Torsion spring 48 which engages support 47 and pipe 41 biases arms 45 and thereby pipe 41 in a position tilted from the vertical in a direction opposite to the direction of travel of pipe 41.

Support 47 is pivotally mounted about a horizontal axis by shaft 49 which is supported by carrier 50. The carrier is attached at each of its free ends by brackets 51 to chains 21. Carrier is mounted upon blocks 52 at each of the free ends and in turn blocks 52 are supported by rollers 53 upon the horizontal surfaces of rails 30. In order to restrain carrier 50 from lateral movement, there is provided rollers 54 pivotally mounted upon blocks 52 and engaging the vertical surfaces of rails 30.

In order to pivot support 47 about shaft 49 and bias the support in a downward position, flat spring 56 mounted upon carrier 50 is attached to support 47.

The end of pipe 41 opposite to hose 42 is provided with valve assembly 57 (FIGS. 11-13). The valve assembly includes spool 58 attached to pipe 41. Spool 58 includes transverse port 59 which communicates with passage 60 connected to the interior of pipe 41. Sleeve 61 surrounds spool 58 and include tapered seat 62 which is adapted to engage tapered face 63 of the spool. Port 59 is sealed at the opposite sides thereof with respect to sleeve 61 by means of seal rings 64. Spring 65 which. engages collar 66 afiixed to pipe 41 urges sleeve to close seat 62 against face 63 in the normal condition.

Transfer pipe assemblies 67 include pipe 68 which serves as a conduit adapted to be connected to a device for producing a flow of fluid therethrough (FIGS. 2-6). Pipes 68 are provided with sockets 69 at one end thereof. In order to form a connection between pipe 68 and pipe 41 which is connected to the tray, it is necessary to convey pipe 41 in the direction of the trays and to advance socket 69 into engagement with sleeve 61 as shown in FIGS. 12 and 13. Advancing socket 69 toward valve assembly 57 results in shoulder 69a intersecting tapered surface 61a of sleeve 61. Once the tapered surface is engaged by the shoulder of socket 69, further movement of the socket toward the valve assembly causes sleeve 61 to be moved from engagement with face 63 of spool 58 with the result that transfer port 59 becomes connected to the interior of socket 69. Seal ring 70 maintains a fluid-tight connection between the socket and the sleeve. Since socket 69 opens sleeve 61 by urging it to compress spring 65, upon removal of the socket, that is upon movement of the socket away from the valve assembly, spring 65 urges sleeve 61 to close seat 62 against face 63.

Each of pipes 68 is mounted with respect to chains 71 by means of guides 72 and brackets 73 attached to the supports. Supports 72 have circular openings for forming a sliding engagement with pipes 68. Thus the guides and brackets form a sliding coupling of pipes 68 to chains 71. Plates 74 are connected to one another by tie rods 75. The tie rods provide ways upon which plates 76 are mounted in a sliding relationship. Bolts 77 which extend through plates 76 support mounts 78 adjacent thereto. Each of the mounts pivotally suppport rollers 79 which are adapted to engage the edges of track 80.

Chains 71 are driven by sprockets 81 which are attached to shafts 82. In turn shafts 82 are driven by sprockets 82a and chains 82b which are connected to the main drive (not shown) for the traveling filter. The drive to sprockets 81 is selected to operate chains 71 at a linear speed which corresponds to the linear speed of tray conveyor chains 21. With this arrangement it can be seen that the drive transmitted by chains 71 through guides 72 carries plates 74 as well as pipes 68 along a predetermined path, the upper reach of which moves in the direction of trays 20 at the same linear velocit as the trays.

By means of the engagement of rollers 79 with track 80, plates 76 are made to follow the motion of the rollers as conditioned by the run of track 80. Since plates 76 are coupled to pipe 68, pipe 68 also follows the movement of rollers 79 in a transverse direction. As a result, it can be seen that the track and rollers, as related to plate 76 and thereby pipe 68, serve as means for successively advancing and retracting the conduit or pipe 68 with respect to its path of travel in order successively to engage and disengage socket 69 with respect to valve assembly 57 connected to the tray.

As shown in FIGS. 3 and 4, track 80 is routed inwardly toward the line of travel of trays 20 when socket 69 has been brought to a position at an angle of approximately 45 from vertical. From this point on the inwardly extending position of track 80 drives rollers 79 and thereby socket 69 toward the line of travel of the trays. When track 80 returns to a direction parallel to the line of travel of trays 20, socket 69 is advanced to its innermost position in which it is adapted to engage valve assembly 57 of the tray.

Prior to the engagement of socket 69 with valve assembly 57, spring 48 biases arms 45 and thereby pipe 41 to a position in a direction opposite to the line of travel of the trays. Consequently valve assembly 57 is in a lagging position with respect to a vertical plane extending through pin 46. At the same time flat spring 56 urges support 47 toward its lowermost position. With valve assembly 57 somewhat depressed and in a lagging position it can be understood that the engagement of socket 69 with valve assembly 57 is facilitated since socket 69 rises and accelerates in a direction parallel to the travel of the trays as engagement with valve assembly 57 begins. The pivotal mounting of support 47 about shaft 49 provides the necessary freedom for socket 69 to elevate valve assembly 57 as engagement is completed. Similarly the pivotal mounting of arms 45 and pipe 41 provide a suflieient degree of freedom for the velocity of socket 69 in the horizontal direction to match that of valve assembly 57. Once engagement is completed arms 45 are moved against the bias of spring 48 to substantially a vertical position.

In order to enable rollers 79 to pass freely along track 80, it is necessary that the axis of rotation of the rollers be maintained in a substantially radial direction whenever the rollers are moving from one horizontal reach to the other of track 80. The tightening of chain 71 to maintain this relationship for the rollers is undesirable since excessive tightening of the chains can accelerate the wear of the chains and sprockets. By means of cogs 83 attached to plates 74 and by means of pins 84 mounted upon sprockets 81, the alignment and positioning of tie rods 75 and thereby rollers 79 can be maintained whenever the rollers pass from one reach to the other of track 80. Pins 84 are disposed in or adjacent pair on sprockets 81. The pair of pins are adapted to engage curved surfaces 83a of cogs 83 during movement between the reaches. In other words pins 84 engage the curve surfaces 83a in a manner analogous to the engagement of a roller chain with respect to the tooth of a chain sprocket. In this Way the correctly aligned position of rollers 79 is maintained for all points along track 80.

After a period of travel of socket 69 in engagement with valve assembly 67, rollers 79 advance to the portion of track 80 where the track is routed outwardly away from the path of travel of the trays. This outwardly extending portion of track causes roller 79 and thereby plate 76 to move away from the tray members and thereby carry socket 69 away from valve assembly 57 until disengagement takes place. Since socket 69 is beginning to move in an outward direction during disengagement, the pivotal mount of support 47 about shaft 49 permits valve assembly 57 to deflect downwardly. At the same time the resilient mounting of pipe 41 by way of arms 45 and spring 48 enables valve assembly 57 to respond along its line of travel to any change in velocity of socket 69 as disengagement takes place.

Since socket 69 is open to the interior of pipe 68, it is necessary to control the connection of pipe 68 to a source of fluid flow whether it be a pressure or a vacuum source. In order to accomplish this control each of pipes 68 are connected to rotor 85 of rotary valve assembly 86 (FIGS. 3, 4 and 5). The connection of pipes 68 to rotor 85 is accomplished by flexible hoses 87. Rotor 85 is provided with a recess 85a connected by tube 88 to each of hoses 87. The stator 89 of valve 86 is provided with a single recess 90 connected to line 91 which can extend to a pressure or a vacuum source.

The drive to rotor 85a begins with one of shafts 82 which is provided with drive gear 92 (FIG. 4). Drive gear 92 is connected through idler gear 93 which in turn meshes with driven gear 94 attached to shaft 95 by key 96 (FIGS. 4 and 5). Shaft 95 extends through stationary housing 97 connected to the stator. The shaft is supported by bushing 98 at the point of junction between stator 89 and housing 97. Rotor 85 is attached with axial freedom but circumferential restraint to shaft 95 by key 99. By means of nut 100 and spring 101 the preloading of rotor 85 against stator 89 can be adjustably selected to prevent leakage between the stator and rotor.

Housing 97 is supported by plate 162 which is attached by screws 103 to support 104. In turn support 104 is mounted by bearings 105 with respect to shafts 82 which carry sprockets 81 for driving chains 71. Support 104 serves as a mount for track 80. Support 106 which is also engaged with shafts 82 by bearings serves to carry bearing 107 for shaft 95 as well as a bearing for idler gear 93.

The gear ratios of gears 92 and 94 are selected to rotate rotor 85 through one complete rotation for each complete passage of one of sockets 69 and pipe 68 about track 80. With this arrangement recess 90 can successively apply pressure or vacuum to each of recesses 85a of rotor 85. By way of example, recess 90 can be formed in an arcuate manner with a center of curvature disposed at the center of shaft 95 and extend in a circumferential manner about shaft 95. With this arrangement, recess 90 is adapted to form a connection to a given recess 85a at the time of engagement as determined by track 80 and to maintain the connection of recess 85a to line 91 for the period of travel of socket 69 in engagement with valve assembly 57. As disengagement of the socket with respect to the valve assembly occurs in response to the change of direction of track 80, recess 85a passes beyond the end portion of recess 90 and thereby the application of pressure or vacuum is terminated.

Filter cake 108 can be removed from filter medium 32 by means of scraper 109 (FIG. 1) by a roller 111 (FIG. 17), or by an air knife or a pulsating air knife 116 (FIG. 16). As shown in Fig. 17 roller 111 which causes the material of cake 108 to adhere to the roller surface can be used to remove the cake from filter medium 32. As shown in FIG. 17 scraper 112 serves to strip the material from roller 111-. After the removal of the filter cake, the filter medium can be subjected to a flow of fluid such as a washing liquid by means of one or more nozzles 113 (FIG. 1).

As shown in FIG. 14 after filter cake 108 i formed upon the filter medium of tray 20 and while top 34 remains engaged with tray 20, a portion of already filtered and washed filter cake material can be applied by delivery pipe 114 to form layer 115 upon filter cake 108. In this way the overall thickness of material disposed upon the filter medium is increased. Since it is known that most materials tend to adhere to themselves better than to another material, layer 115 and filter cake 108 tend to remain togetther after the removal of top 34. As a result the combined layer and cake strip together from the filter medium and fall from the tray conveyor. In other Words by making the overall filter cake heavier, its separation from the filter medium can be insured.

As shown in FIG. filter medium 116 is attached to tray by rod 117 extending through side walls 23 of the tray. The end of filter medium 116 opposite to rod 117 is attached to weighted rod 118. The filter medium is of sutficient length that the medium can be stretched across the cavity of tray 20 and rod 118 can hang down over the trailing end of the tray as shown on the upper reach of trays 20 in FIG. 15. As tops 34 separate from trays 20, the filter medium initially remains in place upon tray 20. As tray 20 advances from the upper reach about sprocket 22, the filter medium under the influence of the weight of filter cake 108, can separate at the end adjacent to rod 118 and swing away from the tray about axes defined by rod 117. The impact resulting from the relative movement of the filter medium with respect to the tray insures that the filter cake is separated from the medium. As trays 20 enter upon the lower reach of conveyor chain 21, the filter medium assumes a substantially vertical position which enables it to be treated by jets of fiuid such as liquid washes, air blasts or the like from one or more of nozzles 119. Nozzles 119 can be positioned to wash both sides of filter medium 116. When the trays begin to move from the lower reach to the upper reach of chain 21, filter medium 116 in response to the weight of rod 118, tends to drape itself across the cavity of the tray until the tray is again completely covered by the medium. Consequently upon arrival at the upper reach of chain 21, the filter medium once more extends in a substantially horizontal plane and completely covers the tray.

As shown in FIG. 14 transfer pipe assemblies 67 can be positioned adjacent to the lower reach of chain 21 in order to apply a fiow of fluid with respect to filter medium 32 after the filter cake has been separated from the filter medium. The flow of fluid can comprise one or more liquid Washes or the application of pressured gas or the like.

The traveling filter of the invention can consist of any number of trays 20 and thus the filter can be of any predetermined length. The number of transfer pipe assemblies 67 is determined by the length of the traveling filter and also by the number of treatments which are to be applied to trays 2t) and the duration of the period of the treatments. The feed of material to be filtered is applied through tops 34 to filter medium 32 of trays 20' shortly after the tops are positioned along their lower reach in registry and in engagement with its trays on their upper reach. By way of example, the first transfer pipe assembly in the direction of movement of the trays can apply vacuum to the trays. As filtration proceeds wash water may be introduced through the tops either separately or concurrently with the engagement of transfer assembly 67 to the tray. After filtration and washing are completed further drying of the cake may be accomplished by the continuation of the application of vacuum to the trays by an additional number of transfer assemblies 67.

The valve timing of rotary valve 86 can be set to provide a connecting or open condition for a brief period after disengagement of socket 69 which valve assembly 57 occurs, for example. This arrangement enables the vacuum applied to line 68 and socket 69 after disengagement to remove any liquid within the line and socket so that they do not spill such liquid prior to their next engagement with the valve assembly.

After separation of the tops from the trays, the filter cake can be removed from the filter medium and a reverse blow can be applied to the filter medium and the cake disposed thereon by means of a transfer assembly 67 disposed adjacent to the. lower reach of chain 21. In addition, as described above, scrapers or rollers or the like can be utilized to remove the filter cake. Once the cake is removed from the filter medium, the filter medium can be washed by the use of sprays or by the use of fiuid fiow delivered to the trays by one or more transfer assemblies 67.

Experience with the traveling filter apparatus of the invention has shown that the edges of end walls 38 of tops 34 can cause wear of filter medium 32 at the locations where the tops move into and move out of register with trays 20 (FIG. 7). The wear is caused by relative motion between the top and the filter medium disposed upon the tray as the tops and trays successively engage and disengage with respect to one another. In addition to causing wear by the relative motion between the tops and the filter medium during separation of a top from a tray, the trailing end Wall 38 of the top tends to move relative to the tray in the direction of travel of the tops and trays and thereby tends to pile up a portion of the filter cake against the inner surface of the end wall. This is an undesirable condition since any accumulation of filter cake on the inner surface of the to can subsequently drop from the top and be lost. In addition, filter cake material falling from the inner surface of the end wall of the top can soil the machinery and the work area, both of which are undesirable operating conditions.

In order to overcome the possibility of causing wear of the filter medium during engagement and disengagement of a top with respect to a tray and in order to prevent dripping and the waste of filter cake material from the tops after separation, tops are driven by the arrangement shown in FIG. 18 while the trays and their drive correspond to that shown in FIG. 1. The trays 20 are attached by brackets 28 to conveyor chain 21 which advances about sprockets 22.

Each of tops 120 is provided with eye brackets 121 extending from side walls 122 of top 1211. Through eye brackets 121 extend rods 123 having stops 124 and 125 at the opposite ends thereof. The end of each of rods 123 opposite to the end adjacent to eye bracket 121 slidably extend through guide 127. Each of guides 127 is connected to support 127a which is attached to chain 126 by means of bracket 128 and pin 129..

As shown in FIG. 18, pin 129 extends into an elongated opening 130 disposed at one end of support 127a. The slot of support 127a, accommodates the relative movement between pin 129 and bracket 128- whenever the top passes about sprockets 130 upon moving between the upper and lower reaches of conveyor chain 126.

As shown in FIG. 19, there is provided collars 131 secured to rods 123. Carrier bar 132 has forked ends which engage rods 123. The forked ends of carrier bar float on rod 123 between collar 131 and the end of spring 121a adjacent thereto. The springs normally urge carrier bars 132 against collar 131 and eye brackets 121 against stops 124. To the carrier bars are attached axles 134 and 135 upon which are mounted wheels 134a and 135a, respectively. Wheels 134a have a greater tread dimension between themselves than do wheels 135a.

On the upper reach of chains 126, eye bracket 121 together with rods 123 move downwardly with respect to chains 126 until collars 131 bear upon guides 127. Springs 121a urge carrier bars 132 against collars 131 so that the carrier bars and the wheel attached thereto descend with rods 123.

Upon approaching and subsequently leaving the lower reach of chains 126, tray 120 assumes an inverted position below chains 126. Upon entering inverted position, top 120 and rods 123 move downwardly with respect to guides 127 and away from chains 126. Eye brackets 121 bear downwardly upon stops 124 and cause rods 123 

